Ion transport in the malaria parasite and parasitised erythrocyte. This work will contribute to the national research effort in parasitology (an area in which the ARC has established a Research Network), as well as laying the groundwork for subsequent efforts (not part of this grant) to develop new antimalarial strategies. Although not yet endemic in Australia, malaria is a serious problem in the local region and, as the major developed nation in the region Australia has an obligation to make ....Ion transport in the malaria parasite and parasitised erythrocyte. This work will contribute to the national research effort in parasitology (an area in which the ARC has established a Research Network), as well as laying the groundwork for subsequent efforts (not part of this grant) to develop new antimalarial strategies. Although not yet endemic in Australia, malaria is a serious problem in the local region and, as the major developed nation in the region Australia has an obligation to make a significant contribution to research in this area. The work proposed here will contribute to Australia's meeting this obligation.Read moreRead less
Amino acid transporters and the chloroquine resistance transporter of the intracellular malaria parasite. This work entails an ongoing collaboration between three independent research groups with highly complementary expertise and experience. It will make a significant contribution to the maintenance of Australia's scientific capabilities and training opportunities. The project will yield important insights into the biology of the causative agent of a major human disease, and the mechanism by ....Amino acid transporters and the chloroquine resistance transporter of the intracellular malaria parasite. This work entails an ongoing collaboration between three independent research groups with highly complementary expertise and experience. It will make a significant contribution to the maintenance of Australia's scientific capabilities and training opportunities. The project will yield important insights into the biology of the causative agent of a major human disease, and the mechanism by which the malaria parasite has developed resistance to antimalarial drugs. Although not yet endemic in Australia, malaria is a serious problem in the local region and this work will help Australia meet its obligations to carry out high-quality research that advances our knowledge in this area.
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Activation of Tissue Factor by a Disulphide-Bond Switch. This project will define the molecular mechanism of activation of tissue factor, the initiator of blood coagulation, and design and test novel antibody therapeutics that block this activation. The applicant suggests that tissue factor is activated by a disulphide-bond switch. Should this hypothesis prove correct it would be the first example of activation of a mammalian protein by this means and, moreover, would be very amenable to therape ....Activation of Tissue Factor by a Disulphide-Bond Switch. This project will define the molecular mechanism of activation of tissue factor, the initiator of blood coagulation, and design and test novel antibody therapeutics that block this activation. The applicant suggests that tissue factor is activated by a disulphide-bond switch. Should this hypothesis prove correct it would be the first example of activation of a mammalian protein by this means and, moreover, would be very amenable to therapeutic intervention because activation occurs on the membrane surface inside blood vessels. Tissue factor activation and thrombus formation is the precipitating event in acute myocardial infarction, unstable angina and ischemic stroke, which are responsible for the majority of deaths in Australia.Read moreRead less
Diversity and Defence: Characterisation of Extremely Variable Defensive Proteins from Sea Urchins. Antibiotic resistance is a global problem. In this project, we will study a new class of potential antibiotics - purpuratins - from sea urchins. Purpuratins are unique when compared to other antimicrobials because of their extreme structural diversity. By investigating that diversity, we will shed new light on biological methods for targeted drug design. This information will be critical to the de ....Diversity and Defence: Characterisation of Extremely Variable Defensive Proteins from Sea Urchins. Antibiotic resistance is a global problem. In this project, we will study a new class of potential antibiotics - purpuratins - from sea urchins. Purpuratins are unique when compared to other antimicrobials because of their extreme structural diversity. By investigating that diversity, we will shed new light on biological methods for targeted drug design. This information will be critical to the development of tailor-made antibiotics that are fine-tuned to kill particular micro-organisms. Our work represents a collaboration between researchers in Australia and the United States. It contributes directly to international scientific co-operation whilst providing high level training for young Australian researchers and students. Read moreRead less
Determining the regulation of vitamin D metabolism. The proposed project will lead to a better understanding of factors that influence the biological function of vitamin D. This will impact in several areas of human health and will provide new avenues for the development of preventative approaches and treatment of cancer. This project is based on the use of 'Frontier Technologies' that will be applied to elucidate basic biological questions.
Structures and Functions of Bacterial Replisomal Proteins. DNA replication in all organisms requires many proteins to interact in a structure called the replisome. The bacterial replisome is assembled about the DnaB helicase, a motor protein that moves along DNA, separating the strands of duplex regions in its path. This project aims to develop understanding of the chemistry of DnaB and other replisomal proteins: their structures, how they work, and how they interact to assemble the replisome. T ....Structures and Functions of Bacterial Replisomal Proteins. DNA replication in all organisms requires many proteins to interact in a structure called the replisome. The bacterial replisome is assembled about the DnaB helicase, a motor protein that moves along DNA, separating the strands of duplex regions in its path. This project aims to develop understanding of the chemistry of DnaB and other replisomal proteins: their structures, how they work, and how they interact to assemble the replisome. This has the potential to lead to design of new antibacterial drugs.
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Innovative Approaches to Membrane Protein Crystallography & Drug Discovery. Membrane proteins make up around 30% of the predicted products from our human genome, are critical for life, and represent the targets of biological agents like hormones and toxins as well as most drugs. Yet these proteins have persistently defied our best efforts to study them: we know very little about what they do or what they look like. This project is aimed at cracking the problem of membrane proteins, while at the ....Innovative Approaches to Membrane Protein Crystallography & Drug Discovery. Membrane proteins make up around 30% of the predicted products from our human genome, are critical for life, and represent the targets of biological agents like hormones and toxins as well as most drugs. Yet these proteins have persistently defied our best efforts to study them: we know very little about what they do or what they look like. This project is aimed at cracking the problem of membrane proteins, while at the same time developing screening methods that can be used to design drugs against them. The long-term benefits to the community will include fundamental new knowledge and the development of new technologies and pharmaceuticals.Read moreRead less
New Proteins from the Mobile Genome: Structure-Led Discovery. The project will provide full descriptions of proteins with the capacity to become mobilised, as well as providing a source of completely novel genes with commercial potential. The proteins and enzymes discovered, and the metabolic processes with which they are identified, will have applications in a wide range of Australian industries: agriculture, forestry, pollution control and pharmaceutical design. This work therefore offers op ....New Proteins from the Mobile Genome: Structure-Led Discovery. The project will provide full descriptions of proteins with the capacity to become mobilised, as well as providing a source of completely novel genes with commercial potential. The proteins and enzymes discovered, and the metabolic processes with which they are identified, will have applications in a wide range of Australian industries: agriculture, forestry, pollution control and pharmaceutical design. This work therefore offers opportunities for many future directions in biotechnology, an area of growing strength in Australia. Read moreRead less
New fragment-based drug design technology by NMR spectroscopy. A new nuclear magnetic resonance (NMR) spectroscopic strategy will be developed for rapid determination of the structure and binding mode of low-molecular weight compounds bound to target proteins. Structural information obtained in this way will greatly accelerate drug development by fragment-based drug design, and NMR spectroscopy is the only method that can deliver this information in solution at atomic resolution. The impact of t ....New fragment-based drug design technology by NMR spectroscopy. A new nuclear magnetic resonance (NMR) spectroscopic strategy will be developed for rapid determination of the structure and binding mode of low-molecular weight compounds bound to target proteins. Structural information obtained in this way will greatly accelerate drug development by fragment-based drug design, and NMR spectroscopy is the only method that can deliver this information in solution at atomic resolution. The impact of the project for pharmaceutical research is further enhanced by extending the range of proteins amenable to NMR analysis by the development of new labelling strategies using stable isotopes, lanthanides and an unnatural amino acid in a state-of-the-art protein production system.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989077
Funder
Australian Research Council
Funding Amount
$225,600.00
Summary
Regional Facility for Real Time Analysis of Molecular Interactions. The ARC Facility for the Analysis of Biomacromolecular Interactions at the University of Wollongong and ANU serves many research groups working at the interface of chemistry and biology with the ultimate aim of drug target identification and drug development. New state-of-the-art instrumentation will enhance their capabilities and enable new activities. Specifically, the new instruments will facilitate characterization of macrom ....Regional Facility for Real Time Analysis of Molecular Interactions. The ARC Facility for the Analysis of Biomacromolecular Interactions at the University of Wollongong and ANU serves many research groups working at the interface of chemistry and biology with the ultimate aim of drug target identification and drug development. New state-of-the-art instrumentation will enhance their capabilities and enable new activities. Specifically, the new instruments will facilitate characterization of macromolecular complexes and enable rapid and precise study in real time of the rates at which molecules interact, under many different experimental conditions. It will strengthen existing collaborations among the partner institutions and provide essential infrastructure for drug development projects.Read moreRead less